defmodule Ecto.Migration do
@moduledoc """
Migrations are used to modify your database schema over time.
This module provides many helpers for migrating the database,
allowing developers to use Elixir to alter their storage in
a way that is database independent.
Migrations typically provide two operations: `up` and `down`,
allowing us to migrate the database forward or roll it back
in case of errors.
In order to manage migrations, Ecto creates a table called
`schema_migrations` in the database, which stores all migrations
that have already been executed. You can configure the name of
this table with the `:migration_source` configuration option.
You can configure a different database for the table that
manages your migrations by setting the `:migration_repo`
configuration option to a different repository.
Ecto also locks the `schema_migrations` table when running
migrations, guaranteeing two different servers cannot run the same
migration at the same time.
## Creating your first migration
Migrations are defined inside the "priv/REPO/migrations" where REPO
is the last part of the repository name in underscore. For example,
migrations for `MyApp.Repo` would be found in "priv/repo/migrations".
For `MyApp.CustomRepo`, it would be found in "priv/custom_repo/migrations".
Each file in the migrations directory has the following structure:
```text
NUMBER_NAME.exs
```
The NUMBER is a unique number that identifies the migration. It is
usually the timestamp of when the migration was created. The NAME
must also be unique and it quickly identifies what the migration
does. For example, if you need to track the "weather" in your system,
you can start a new file at "priv/repo/migrations/20190417140000_add_weather_table.exs"
that will have the following contents:
defmodule MyRepo.Migrations.AddWeatherTable do
use Ecto.Migration
def up do
create table("weather") do
add :city, :string, size: 40
add :temp_lo, :integer
add :temp_hi, :integer
add :prcp, :float
timestamps()
end
end
def down do
drop table("weather")
end
end
The `up/0` function is responsible to migrate your database forward.
the `down/0` function is executed whenever you want to rollback.
The `down/0` function must always do the opposite of `up/0`.
Inside those functions, we invoke the API defined in this module,
you will find conveniences for managing tables, indexes, columns,
references, as well as running custom SQL commands.
To run a migration, we generally use Mix tasks. For example, you can
run the migration above by going to the root of your project and
typing:
$ mix ecto.migrate
You can also roll it back by calling:
$ mix ecto.rollback --step 1
Note rollback requires us to say how much we want to rollback.
On the other hand, `mix ecto.migrate` will always run all pending
migrations.
In practice, we don't create migration files by hand either, we
typically use `mix ecto.gen.migration` to generate the file with
the proper timestamp and then we just fill in its contents:
$ mix ecto.gen.migration add_weather_table
## Mix tasks
As seen above, Ecto provides many Mix tasks to help developers work
with migrations. We summarize them below:
* `mix ecto.gen.migration` - generates a
migration that the user can fill in with particular commands
* `mix ecto.migrate` - migrates a repository
* `mix ecto.migrations` - shows all migrations and their status
* `mix ecto.rollback` - rolls back a particular migration
Run `mix help COMMAND` for more information on a particular command.
For a lower level API for running migrations, see `Ecto.Migrator`.
## Change
Having to write both `up/0` and `down/0` functions for every
migration is tedious and error prone. For this reason, Ecto allows
you to defined a `change/0` callback with all of the code you want
to execute when migrating and Ecto will automatically figure out
the `down/0` for you. For example, the migration above can be
written as:
defmodule MyRepo.Migrations.AddWeatherTable do
use Ecto.Migration
def change do
create table("weather") do
add :city, :string, size: 40
add :temp_lo, :integer
add :temp_hi, :integer
add :prcp, :float
timestamps()
end
end
end
However, note that not all commands are reversible. Trying to rollback
a non-reversible command will raise an `Ecto.MigrationError`.
A notable command in this regard is `execute/2`, which is reversible in
`change/0` by accepting a pair of plain SQL strings. The first is run on
forward migrations (`up/0`) and the second when rolling back (`down/0`).
If `up/0` and `down/0` are implemented in a migration, they take precedence,
and `change/0` isn't invoked.
## Field Types
The Ecto primitive types are mapped to the appropriate database
type by the various database adapters. For example, `:string` is
converted to `:varchar`, `:binary` to `:bytea` or `:blob`, and so on.
In particular, note that:
* the `:string` type in migrations by default has a limit of 255 characters.
If you need more or less characters, pass the `:size` option, such
as `add :field, :string, size: 10`. If you don't want to impose a limit,
most databases support a `:text` type or similar
* the `:binary` type in migrations by default has no size limit. If you want
to impose a limit, pass the `:size` option accordingly. In MySQL, passing
the size option changes the underlying field from "blob" to "varbinary"
Any other type will be given as is to the database. For example, you
can use `:text`, `:char`, or `:varchar` as types. Types that have spaces
in their names can be wrapped in double quotes, such as `:"int unsigned"`,
`:"time without time zone"`, etc.
## Executing and flushing
Instructions inside of migrations are not executed immediately. Instead
they are performed after the relevant `up`, `change`, or `down` callback
terminates.
However, in some situations you may want to guarantee that all of the
previous steps have been executed before continuing. This is useful when
you need to apply a set of changes to the table before continuing with the
migration. This can be done with `flush/0`:
def up do
...
flush()
...
end
However `flush/0` will raise if it would be called from `change` function when doing a rollback.
To avoid that we recommend to use `execute/2` with anonymous functions instead.
For more information and example usage please take a look at `execute/2` function.
## Comments
Migrations where you create or alter a table support specifying table
and column comments. The same can be done when creating constraints
and indexes. Not all databases support this feature.
def up do
create index("posts", [:name], comment: "Index Comment")
create constraint("products", "price_must_be_positive", check: "price > 0", comment: "Constraint Comment")
create table("weather", prefix: "north_america", comment: "Table Comment") do
add :city, :string, size: 40, comment: "Column Comment"
timestamps()
end
end
## Repo configuration
The following migration configuration options are available for a given repository:
* `:migration_source` - Version numbers of migrations will be saved in a
table named `schema_migrations` by default. You can configure the name of
the table via:
config :app, App.Repo, migration_source: "my_migrations"
* `:migration_primary_key` - By default, Ecto uses the `:id` column with type
`:bigserial`, but you can configure it via:
config :app, App.Repo, migration_primary_key: [name: :uuid, type: :binary_id]
config :app, App.Repo, migration_primary_key: false
* `:migration_foreign_key` - By default, Ecto uses the migration_primary_key type
for foreign keys when references/2 is used, but you can configure it via:
config :app, App.Repo, migration_foreign_key: [column: :uuid, type: :binary_id]
* `:migration_timestamps` - By default, Ecto uses the `:naive_datetime` as the type,
`:inserted_at` as the name of the column for storing insertion times, `:updated_at` as
the name of the column for storing last-updated-at times, but you can configure it
via:
config :app, App.Repo, migration_timestamps: [
type: :utc_datetime,
inserted_at: :created_at,
updated_at: :changed_at
]
* `:migration_lock` - By default, Ecto will lock the migration table. This allows
multiple nodes to attempt to run migrations at the same time but only one will
succeed. You can disable the `migration_lock` by setting it to `false`
config :app, App.Repo, migration_lock: false
* `:migration_default_prefix` - Ecto defaults to `nil` for the database prefix for
migrations, but you can configure it via:
config :app, App.Repo, migration_default_prefix: "my_prefix"
* `:migration_repo` - The migration repository is where the table managing the
migrations will be stored (`migration_source` defines the table name). It defaults
to the given repository itself but you can configure it via:
config :app, App.Repo, migration_repo: App.MigrationRepo
* `:priv` - the priv directory for the repo with the location of important assets,
such as migrations. For a repository named `MyApp.FooRepo`, `:priv` defaults to
"priv/foo_repo" and migrations should be placed at "priv/foo_repo/migrations"
* `:start_apps_before_migration` - A list of applications to be started before
running migrations. Used by `Ecto.Migrator.with_repo/3` and the migration tasks:
config :app, App.Repo, start_apps_before_migration: [:ssl, :some_custom_logger]
## Prefixes
Migrations support specifying a table prefix or index prefix which will
target either a schema (if using PostgreSQL) or a different database (if using
MySQL). If no prefix is provided, the default schema or database is used.
Any reference declared in the table migration refers by default to the table
with the same declared prefix. The prefix is specified in the table options:
def up do
create table("weather", prefix: "north_america") do
add :city, :string, size: 40
add :temp_lo, :integer
add :temp_hi, :integer
add :prcp, :float
add :group_id, references(:groups)
timestamps()
end
create index("weather", [:city], prefix: "north_america")
end
Note: if using MySQL with a prefixed table, you must use the same prefix
for the references since cross-database references are not supported.
When using a prefixed table with either MySQL or PostgreSQL, you must use the
same prefix for the index field to ensure that you index the prefix-qualified
table.
## Transaction Callbacks
If possible, each migration runs inside a transaction. This is true for Postgres,
but not true for MySQL, as the latter does not support DDL transactions.
In some rare cases, you may need to execute some common behavior after beginning
a migration transaction, or before committing that transaction. For instance, one
might desire to set a `lock_timeout` for each lock in the migration transaction.
You can do so by defining `c:after_begin/0` and `c:before_commit/0` callbacks to
your migration.
However, if you need do so for every migration module, implement this callback
for every migration can be quite repetitive. Luckily, you can handle this by
providing your migration module:
defmodule MyApp.Migration do
defmacro __using__(_) do
quote do
use Ecto.Migration
def after_begin() do
repo().query! "SET lock_timeout TO '5s'"
end
end
end
end
Then in your migrations you can `use MyApp.Migration` to share this behavior
among all your migrations.
"""
@doc """
Migration code to run immediately after the transaction is opened.
Keep in mind that it is treated like any normal migration code, and should
consider both the up *and* down cases of the migration.
"""
@callback after_begin() :: term
@doc """
Migration code to run immediately before the transaction is closed.
Keep in mind that it is treated like any normal migration code, and should
consider both the up *and* down cases of the migration.
"""
@callback before_commit() :: term
@optional_callbacks after_begin: 0, before_commit: 0
defmodule Index do
@moduledoc """
Used internally by adapters.
To define an index in a migration, see `Ecto.Migration.index/3`.
"""
defstruct table: nil,
prefix: nil,
name: nil,
columns: [],
unique: false,
concurrently: false,
using: nil,
include: [],
where: nil,
comment: nil,
options: nil
@type t :: %__MODULE__{
table: String.t,
prefix: atom,
name: atom,
columns: [atom | String.t],
unique: boolean,
concurrently: boolean,
using: atom | String.t,
include: [atom | String.t],
where: atom | String.t,
comment: String.t | nil,
options: String.t
}
end
defmodule Table do
@moduledoc """
Used internally by adapters.
To define a table in a migration, see `Ecto.Migration.table/2`.
"""
defstruct name: nil, prefix: nil, comment: nil, primary_key: true, engine: nil, options: nil
@type t :: %__MODULE__{name: String.t, prefix: atom | nil, comment: String.t | nil, primary_key: boolean,
engine: atom, options: String.t}
end
defmodule Reference do
@moduledoc """
Used internally by adapters.
To define a reference in a migration, see `Ecto.Migration.references/2`.
"""
defstruct name: nil, prefix: nil, table: nil, column: :id, type: :bigserial,
on_delete: :nothing, on_update: :nothing, validate: true,
with: [], match: nil
@type t :: %__MODULE__{table: String.t, prefix: atom | nil, column: atom, type: atom,
on_delete: atom, on_update: atom, validate: boolean,
with: list, match: atom | nil}
end
defmodule Constraint do
@moduledoc """
Used internally by adapters.
To define a constraint in a migration, see `Ecto.Migration.constraint/3`.
"""
defstruct name: nil, table: nil, check: nil, exclude: nil, prefix: nil, comment: nil, validate: true
@type t :: %__MODULE__{name: atom, table: String.t, prefix: atom | nil,
check: String.t | nil, exclude: String.t | nil, comment: String.t | nil, validate: boolean}
end
defmodule Command do
@moduledoc """
Used internally by adapters.
This represents the up and down legs of a reversible raw command
that is usually defined with `Ecto.Migration.execute/1`.
To define a reversible command in a migration, see `Ecto.Migration.execute/2`.
"""
defstruct up: nil, down: nil
@type t :: %__MODULE__{up: String.t, down: String.t}
end
alias Ecto.Migration.Runner
@doc false
defmacro __using__(_) do
quote location: :keep do
import Ecto.Migration
@disable_ddl_transaction false
@disable_migration_lock false
@before_compile Ecto.Migration
end
end
@doc false
defmacro __before_compile__(_env) do
quote do
def __migration__ do
[
disable_ddl_transaction: @disable_ddl_transaction,
disable_migration_lock: @disable_migration_lock
]
end
end
end
@doc """
Creates a table.
By default, the table will also include an `:id` primary key field that
has a type of `:bigserial`. Check the `table/2` docs for more information.
## Examples
create table(:posts) do
add :title, :string, default: "Untitled"
add :body, :text
timestamps()
end
"""
defmacro create(object, do: block) do
expand_create(object, :create, block)
end
@doc """
Creates a table if it does not exist.
Works just like `create/2` but does not raise an error when the table
already exists.
"""
defmacro create_if_not_exists(object, do: block) do
expand_create(object, :create_if_not_exists, block)
end
defp expand_create(object, command, block) do
quote do
table = %Table{} = unquote(object)
Runner.start_command({unquote(command), Ecto.Migration.__prefix__(table)})
if primary_key = table.primary_key && Ecto.Migration.__primary_key__() do
{name, type, opts} = primary_key
add(name, type, opts)
end
unquote(block)
Runner.end_command()
table
end
end
@doc """
Alters a table.
## Examples
alter table("posts") do
add :summary, :text
modify :title, :text
remove :views
end
"""
defmacro alter(object, do: block) do
quote do
table = %Table{} = unquote(object)
Runner.start_command({:alter, Ecto.Migration.__prefix__(table)})
unquote(block)
Runner.end_command()
end
end
@doc """
Creates one of the following:
* an index
* a table with only the :id primary key
* a constraint
When reversing (in a `change/0` running backwards), indexes are only dropped
if they exist, and no errors are raised. To enforce dropping an index, use
`drop/1`.
## Examples
create index("posts", [:name])
create table("version")
create constraint("products", "price_must_be_positive", check: "price > 0")
"""
def create(%Index{} = index) do
Runner.execute {:create, __prefix__(index)}
index
end
def create(%Constraint{} = constraint) do
Runner.execute {:create, __prefix__(constraint)}
constraint
end
def create(%Table{} = table) do
do_create table, :create
table
end
@doc """
Creates an index or a table with only `:id` field if one does not yet exist.
## Examples
create_if_not_exists index("posts", [:name])
create_if_not_exists table("version")
"""
def create_if_not_exists(%Index{} = index) do
Runner.execute {:create_if_not_exists, __prefix__(index)}
end
def create_if_not_exists(%Table{} = table) do
do_create table, :create_if_not_exists
end
defp do_create(table, command) do
columns =
if primary_key = table.primary_key && Ecto.Migration.__primary_key__() do
{name, type, opts} = primary_key
[{:add, name, type, opts}]
else
[]
end
Runner.execute {command, __prefix__(table), columns}
end
@doc """
Drops one of the following:
* an index
* a table
* a constraint
## Examples
drop index("posts", [:name])
drop table("posts")
drop constraint("products", "price_must_be_positive")
drop index("posts", [:name]), mode: :cascade
drop table("posts"), mode: :cascade
## Options
* `:mode` - when set to `:cascade`, automatically drop objects that depend
on the index, and in turn all objects that depend on those objects
on the table. Default is `:restrict`
"""
def drop(%{} = index_or_table_or_constraint, opts \\ []) when is_list(opts) do
Runner.execute {:drop, __prefix__(index_or_table_or_constraint), Keyword.get(opts, :mode, :restrict)}
index_or_table_or_constraint
end
@doc """
Drops a table or index if it exists.
Does not raise an error if the specified table or index does not exist.
## Examples
drop_if_exists index("posts", [:name])
drop_if_exists table("posts")
drop_if_exists index("posts", [:name]), mode: :cascade
drop_if_exists table("posts"), mode: :cascade
## Options
* `:mode` - when set to `:cascade`, automatically drop objects that depend
on the index, and in turn all objects that depend on those objects
on the table. Default is `:restrict`
"""
def drop_if_exists(%{} = index_or_table, opts \\ []) when is_list(opts) do
Runner.execute {:drop_if_exists, __prefix__(index_or_table), Keyword.get(opts, :mode, :restrict)}
index_or_table
end
@doc """
Returns a table struct that can be given to `create/2`, `alter/2`, `drop/1`,
etc.
## Examples
create table("products") do
add :name, :string
add :price, :decimal
end
drop table("products")
create table("products", primary_key: false) do
add :name, :string
add :price, :decimal
end
## Options
* `:primary_key` - when `false`, a primary key field is not generated on table
creation.
* `:engine` - customizes the table storage for supported databases. For MySQL,
the default is InnoDB.
* `:prefix` - the prefix for the table. This prefix will automatically be used
for all constraints and references defined for this table unless explicitly
overridden in said constraints/references.
* `:comment` - adds a comment to the table.
* `:options` - provide custom options that will be appended after the generated
statement. For example, "WITH", "INHERITS", or "ON COMMIT" clauses.
"""
def table(name, opts \\ [])
def table(name, opts) when is_atom(name) do
table(Atom.to_string(name), opts)
end
def table(name, opts) when is_binary(name) and is_list(opts) do
struct(%Table{name: name}, opts)
end
@doc ~S"""
Returns an index struct that can be given to `create/1`, `drop/1`, etc.
Expects the table name as the first argument and the index field(s) as
the second. The fields can be atoms, representing columns, or strings,
representing expressions that are sent as-is to the database.
## Options
* `:name` - the name of the index. Defaults to "#{table}_#{column}_index".
* `:unique` - indicates whether the index should be unique. Defaults to
`false`.
* `:concurrently` - indicates whether the index should be created/dropped
concurrently.
* `:using` - configures the index type.
* `:prefix` - specify an optional prefix for the index.
* `:where` - specify conditions for a partial index.
* `:include` - specify fields for a covering index. This is not supported
by all databases. For more information on PostgreSQL support, please
[read the official docs](https://www.postgresql.org/docs/current/indexes-index-only-scans.html).
* `:comment` - adds a comment to the index.
## Adding/dropping indexes concurrently
PostgreSQL supports adding/dropping indexes concurrently (see the
[docs](http://www.postgresql.org/docs/current/static/sql-createindex.html)).
However, this feature does not work well with the transactions used by
Ecto to guarantee integrity during migrations.
Therefore, to migrate indexes concurrently, you need to set
both `@disable_ddl_transaction` and `@disable_migration_lock` to true:
defmodule MyRepo.Migrations.CreateIndexes do
use Ecto.Migration
@disable_ddl_transaction true
@disable_migration_lock true
def change do
create index("posts", [:slug], concurrently: true)
end
end
Disabling DDL transactions removes the guarantee that all of the changes
in the migration will happen at once. Disabling the migration lock removes
the guarantee only a single node will run a given migration if multiple
nodes are attempting to migrate at the same time.
Since running migrations outside a transaction and without locks can be
dangerous, consider performing very few operations in migrations that add
concurrent indexes. We recommend to run migrations with concurrent indexes
in isolation and disable those features only temporarily.
## Index types
When creating an index, the index type can be specified with the `:using`
option. The `:using` option can be an atom or a string, and its value is
passed to the generated `USING` clause as-is.
For example, PostgreSQL supports several index types like B-tree (the
default), Hash, GIN, and GiST. More information on index types can be found
in the [PostgreSQL docs](http://www.postgresql.org/docs/current/indexes-types.html).
## Partial indexes
Databases like PostgreSQL and MSSQL support partial indexes.
A partial index is an index built over a subset of a table. The subset
is defined by a conditional expression using the `:where` option.
The `:where` option can be an atom or a string; its value is passed
to the generated `WHERE` clause as-is.
More information on partial indexes can be found in the [PostgreSQL
docs](http://www.postgresql.org/docs/current/indexes-partial.html).
## Examples
# With no name provided, the name of the below index defaults to
# products_category_id_sku_index
create index("products", [:category_id, :sku], unique: true)
# The name can also be set explicitly
create index("products", [:category_id, :sku], name: :my_special_name)
# Indexes can be added concurrently
create index("products", [:category_id, :sku], concurrently: true)
# The index type can be specified
create index("products", [:name], using: :hash)
# Partial indexes are created by specifying a :where option
create index("products", [:user_id], where: "price = 0", name: :free_products_index)
# Covering indexes are created by specifying a :include option
create index("products", [:user_id], include: [:category_id])
Indexes also support custom expressions. Some databases may require the
index expression to be written between parentheses:
# Create an index on a custom expression
create index("products", ["(lower(name))"], name: :products_lower_name_index)
# Create a tsvector GIN index on PostgreSQL
create index("products", ["(to_tsvector('english', name))"],
name: :products_name_vector, using: "GIN")
"""
def index(table, columns, opts \\ [])
def index(table, columns, opts) when is_atom(table) do
index(Atom.to_string(table), columns, opts)
end
def index(table, column, opts) when is_binary(table) and is_atom(column) do
index(table, [column], opts)
end
def index(table, columns, opts) when is_binary(table) and is_list(columns) and is_list(opts) do
validate_index_opts!(opts)
index = struct(%Index{table: table, columns: columns}, opts)
%{index | name: index.name || default_index_name(index)}
end
@doc """
Shortcut for creating a unique index.
See `index/3` for more information.
"""
def unique_index(table, columns, opts \\ [])
def unique_index(table, columns, opts) when is_list(opts) do
index(table, columns, [unique: true] ++ opts)
end
defp default_index_name(index) do
[index.table, index.columns, "index"]
|> List.flatten
|> Enum.map(&to_string(&1))
|> Enum.map(&String.replace(&1, ~r"[^\w_]", "_"))
|> Enum.map(&String.replace_trailing(&1, "_", ""))
|> Enum.join("_")
|> String.to_atom
end
@doc """
Executes arbitrary SQL, anonymous function or a keyword command.
The argument is typically a string, containing the SQL command to be executed.
Keyword commands exist for non-SQL adapters and are not used in most situations.
Supplying an anonymous function does allow for arbitrary code to execute as
part of the migration. This is most often used in combination with `repo/0`
by library authors who want to create high-level migration helpers.
Reversible commands can be defined by calling `execute/2`.
## Examples
execute "CREATE EXTENSION postgres_fdw"
execute create: "posts", capped: true, size: 1024
execute(fn -> repo().query!("SELECT $1::integer + $2", [40, 2], [log: :info]) end)
execute(fn -> repo().update_all("posts", set: [published: true]) end)
"""
def execute(command) when is_binary(command) or is_function(command, 0) or is_list(command) do
Runner.execute command
end
@doc """
Executes reversible SQL commands.
This is useful for database-specific functionality that does not
warrant special support in Ecto, for example, creating and dropping
a PostgreSQL extension. The `execute/2` form avoids having to define
separate `up/0` and `down/0` blocks that each contain an `execute/1`
expression.
The allowed parameters are explained in `execute/1`.
## Examples
defmodule MyApp.MyMigration do
use Ecto.Migration
def change do
execute "CREATE EXTENSION postgres_fdw", "DROP EXTENSION postgres_fdw"
execute(&execute_up/0, &execute_down/0)
end
defp execute_up, do: repo().query!("select 'Up query …';", [], [log: :info])
defp execute_down, do: repo().query!("select 'Down query …';", [], [log: :info])
end
"""
def execute(up, down) when (is_binary(up) or is_function(up, 0) or is_list(up)) and
(is_binary(down) or is_function(down, 0) or is_list(down)) do
Runner.execute %Command{up: up, down: down}
end
@doc """
Gets the migrator direction.
"""
@spec direction :: :up | :down
def direction do
Runner.migrator_direction()
end
@doc """
Gets the migrator repo.
"""
@spec repo :: Ecto.Repo.t
def repo do
Runner.repo()
end
@doc """
Gets the migrator prefix.
"""
def prefix do
Runner.prefix()
end
@doc """
Adds a column when creating or altering a table.
This function also accepts Ecto primitive types as column types
that are normalized by the database adapter. For example,
`:string` is converted to `:varchar`, `:binary` to `:bits` or `:blob`,
and so on.
However, the column type is not always the same as the type used in your
schema. For example, a schema that has a `:string` field can be supported by
columns of type `:char`, `:varchar`, `:text`, and others. For this reason,
this function also accepts `:text` and other type annotations that are native
to the database. These are passed to the database as-is.
To sum up, the column type may be either an Ecto primitive type,
which is normalized in cases where the database does not understand it,
such as `:string` or `:binary`, or a database type which is passed as-is.
Custom Ecto types like `Ecto.UUID` are not supported because
they are application-level concerns and may not always map to the database.
Note: It may be necessary to quote case-sensitive, user-defined type names.
For example, PostgreSQL normalizes all identifiers to lower case unless
they are wrapped in double quotes. To ensure a case-sensitive type name
is sent properly, it must be defined `:'"LikeThis"'` or `:"\"LikeThis\""`.
This is not necessary for column names because Ecto quotes them automatically.
Type names are not automatically quoted because they may be expressions such
as `varchar(255)`.
## Examples
create table("posts") do
add :title, :string, default: "Untitled"
end
alter table("posts") do
add :summary, :text # Database type
add :object, :map # Elixir type which is handled by the database
add :custom, :'"UserDefinedType"' # A case-sensitive, user-defined type name
end
## Options
* `:primary_key` - when `true`, marks this field as the primary key.
If multiple fields are marked, a composite primary key will be created.
* `:default` - the column's default value. It can be a string, number, empty
list, list of strings, list of numbers, or a fragment generated by
`fragment/1`.
* `:null` - determines whether the column accepts null values. When not specified,
the database will use its default behaviour (which is to treat the column as nullable
in most databases).
* `:size` - the size of the type (for example, the number of characters).
The default is no size, except for `:string`, which defaults to `255`.
* `:precision` - the precision for a numeric type. Required when `:scale` is
specified.
* `:scale` - the scale of a numeric type. Defaults to `0`.
* `:comment` - adds a comment to the added column.
* `:after` - positions field after the specified one. Only supported on MySQL,
it is ignored by other databases.
"""
def add(column, type, opts \\ []) when is_atom(column) and is_list(opts) do
validate_precision_opts!(opts, column)
validate_type!(type)
Runner.subcommand {:add, column, type, opts}
end
@doc """
Adds a column if it not exists yet when altering a table.
If the `type` value is a `%Reference{}`, it is used to add a constraint.
`type` and `opts` are exactly the same as in `add/3`.
This command is not reversible as Ecto does not know about column existence before the creation attempt.
## Examples
alter table("posts") do
add_if_not_exists :title, :string, default: ""
end
"""
def add_if_not_exists(column, type, opts \\ []) when is_atom(column) and is_list(opts) do
validate_precision_opts!(opts, column)
validate_type!(type)
Runner.subcommand {:add_if_not_exists, column, type, opts}
end
@doc """
Renames a table.
## Examples
rename table("posts"), to: table("new_posts")
"""
def rename(%Table{} = table_current, to: %Table{} = table_new) do
Runner.execute {:rename, __prefix__(table_current), __prefix__(table_new)}
table_new
end
@doc """
Renames a column.
Note that this occurs outside of the `alter` statement.
## Examples
rename table("posts"), :title, to: :summary
"""
def rename(%Table{} = table, current_column, to: new_column) when is_atom(current_column) and is_atom(new_column) do
Runner.execute {:rename, __prefix__(table), current_column, new_column}
table
end
@doc """
Generates a fragment to be used as a default value.
## Examples
create table("posts") do
add :inserted_at, :naive_datetime, default: fragment("now()")
end
"""
def fragment(expr) when is_binary(expr) do
{:fragment, expr}
end
@doc """
Adds `:inserted_at` and `:updated_at` timestamp columns.
Those columns are of `:naive_datetime` type and by default cannot be null. A
list of `opts` can be given to customize the generated fields.
Following options will override the repo configuration specified by
`:migration_timestamps` option.
## Options
* `:inserted_at` - the name of the column for storing insertion times.
Setting it to `false` disables the column.
* `:updated_at` - the name of the column for storing last-updated-at times.
Setting it to `false` disables the column.
* `:type` - the type of the `:inserted_at` and `:updated_at` columns.
Defaults to `:naive_datetime`.
* `:default` - the columns' default value. It can be a string, number, empty
list, list of strings, list of numbers, or a fragment generated by
`fragment/1`.
"""
def timestamps(opts \\ []) when is_list(opts) do
opts = Keyword.merge(Runner.repo_config(:migration_timestamps, []), opts)
opts = Keyword.put_new(opts, :null, false)
{type, opts} = Keyword.pop(opts, :type, :naive_datetime)
{inserted_at, opts} = Keyword.pop(opts, :inserted_at, :inserted_at)
{updated_at, opts} = Keyword.pop(opts, :updated_at, :updated_at)
if inserted_at != false, do: add(inserted_at, type, opts)
if updated_at != false, do: add(updated_at, type, opts)
end
@doc """
Modifies the type of a column when altering a table.
This command is not reversible unless the `:from` option is provided.
When the `:from` option is set, the adapter will try to drop
the corresponding foreign key constraints before modifying the type.
Generally speaking, you want to pass the type and each option
you are modifying to `:from`, so the column can be rolled back properly.
However, note that `:from` cannot be be used to modify primary keys,
as those are generally trickier to revert.
See `add/3` for more information on supported types.
If you want to modify a column without changing its type,
such as adding or dropping a null constraints, consider using
the `execute/2` command with the relevant SQL command instead
of `modify/3`, if supported by your database. This may avoid
redundant type updates and be more efficient, as an unnecessary
type update can lock the table, even if the type actually
doesn't change.
## Examples
alter table("posts") do
modify :title, :text
end
# Self rollback when using the :from option
alter table("posts") do
modify :title, :text, from: :string
end
# Modify column with rollback options
alter table("posts") do
modify :title, :text, null: false, from: {:string, null: true}
end
## Options
* `:null` - determines whether the column accepts null values. If this option is
not set, the nullable behaviour of the underlying column is not modified.
* `:default` - changes the default value of the column.
* `:from` - specifies the current type and options of the column.
* `:size` - specifies the size of the type (for example, the number of characters).
The default is no size.
* `:precision` - the precision for a numeric type. Required when `:scale` is
specified.
* `:scale` - the scale of a numeric type. Defaults to `0`.
* `:comment` - adds a comment to the modified column.
"""
def modify(column, type, opts \\ []) when is_atom(column) and is_list(opts) do
validate_precision_opts!(opts, column)
validate_type!(type)
Runner.subcommand {:modify, column, type, opts}
end
@doc """
Removes a column when altering a table.
This command is not reversible as Ecto does not know what type it should add
the column back as. See `remove/3` as a reversible alternative.
## Examples
alter table("posts") do
remove :title
end
"""
def remove(column) when is_atom(column) do
Runner.subcommand {:remove, column}
end
@doc """
Removes a column in a reversible way when altering a table.
`type` and `opts` are exactly the same as in `add/3`, and
they are used when the command is reversed.
If the `type` value is a `%Reference{}`, it is used to remove the constraint.
## Examples
alter table("posts") do
remove :title, :string, default: ""
end
"""
def remove(column, type, opts \\ []) when is_atom(column) do
validate_type!(type)
Runner.subcommand {:remove, column, type, opts}
end
@doc """
Removes a column only if the column exists when altering the constraint if the reference type is passed
once it only has the constraint name on reference structure.
This command is not reversible as Ecto does not know about column existence before the removal attempt.
## Examples
alter table("posts") do
remove_if_exists :title, :string
end
"""
def remove_if_exists(column, type) when is_atom(column) do
validate_type!(type)
Runner.subcommand {:remove_if_exists, column, type}
end
@doc ~S"""
Defines a foreign key.
By default it assumes you are linking to the referenced table
via its primary key with name `:id`. If you are using a non-default
key setup (e.g. using `uuid` type keys) you must ensure you set the
options, such as `:name` and `:type`, to match your target key.
## Examples
create table("products") do
add :group_id, references("groups")
end
create table("categories") do
add :group_id, :integer
# A composite foreign that points from categories (product_id, group_id)
# to products (id, group_id)
add :product_id, references("products", with: [group_id: :group_id])
end
## Options
* `:name` - The name of the underlying reference, which defaults to
"#{table}_#{column}_fkey".
* `:column` - The column name in the referenced table, which defaults to `:id`.
* `:prefix` - The prefix for the reference. Defaults to the prefix
defined by the block's `table/2` struct (the "products" table in
the example above), or `nil`.
* `:type` - The foreign key type, which defaults to `:bigserial`.
* `:on_delete` - What to do if the referenced entry is deleted. May be
`:nothing` (default), `:delete_all`, `:nilify_all`, or `:restrict`.
* `:on_update` - What to do if the referenced entry is updated. May be
`:nothing` (default), `:update_all`, `:nilify_all`, or `:restrict`.
* `:validate` - Whether or not to validate the foreign key constraint on
creation or not. Only available in PostgreSQL, and should be followed by
a command to validate the foreign key in a following migration if false.
* `:with` - defines additional keys to the foreign key in order to build
a composite primary key
* `:match` - select if the match is `:simple`, `:partial`, or `:full`. This is
[supported only by PostgreSQL](https://www.postgresql.org/docs/current/sql-createtable.html)
at the moment.
"""
def references(table, opts \\ [])
def references(table, opts) when is_atom(table) do
references(Atom.to_string(table), opts)
end
def references(table, opts) when is_binary(table) and is_list(opts) do
opts = Keyword.merge(foreign_key_repo_opts(), opts)
reference = struct(%Reference{table: table}, opts)
unless reference.on_delete in [:nothing, :delete_all, :nilify_all, :restrict] do
raise ArgumentError, "unknown :on_delete value: #{inspect reference.on_delete}"
end
unless reference.on_update in [:nothing, :update_all, :nilify_all, :restrict] do
raise ArgumentError, "unknown :on_update value: #{inspect reference.on_update}"
end
reference
end
defp foreign_key_repo_opts() do
case Runner.repo_config(:migration_primary_key, []) do
false -> []
opts -> opts
end
|> Keyword.take([:type])
|> Keyword.merge(Runner.repo_config(:migration_foreign_key, []))
end
@doc ~S"""
Defines a constraint (either a check constraint or an exclusion constraint)
to be evaluated by the database when a row is inserted or updated.
## Examples
create constraint("users", :price_must_be_positive, check: "price > 0")
create constraint("size_ranges", :no_overlap, exclude: ~s|gist (int4range("from", "to", '[]') WITH &&)|)
drop constraint("products", "price_must_be_positive")
## Options
* `:check` - A check constraint expression. Required when creating a check constraint.
* `:exclude` - An exclusion constraint expression. Required when creating an exclusion constraint.
* `:prefix` - The prefix for the table.
* `:validate` - Whether or not to validate the constraint on creation (true by default). Only
available in PostgreSQL, and should be followed by a command to validate the new constraint in
a following migration if false.
* `:comment` - adds a comment to the constraint.
"""
def constraint(table, name, opts \\ [])
def constraint(table, name, opts) when is_atom(table) do
constraint(Atom.to_string(table), name, opts)
end
def constraint(table, name, opts) when is_binary(table) and is_list(opts) do
struct(%Constraint{table: table, name: name}, opts)
end
@doc "Executes queue migration commands."
defmacro flush do
quote do
if direction() == :down and not function_exported?(__MODULE__, :down, 0) do
raise "calling flush() inside change when doing rollback is not supported."
else
Runner.flush()
end
end
end
# Validation helpers
defp validate_type!(:datetime) do
raise ArgumentError, "the :datetime type in migrations is not supported, " <>
"please use :utc_datetime or :naive_datetime instead"
end
defp validate_type!(type) when is_atom(type) do
case Atom.to_string(type) do
"Elixir." <> _ ->
raise ArgumentError,
"#{inspect type} is not a valid database type, " <>
"please use an atom like :string, :text and so on"
_ ->
:ok
end
end
defp validate_type!({type, subtype}) when is_atom(type) and is_atom(subtype) do
validate_type!(subtype)
end
defp validate_type!({type, subtype}) when is_atom(type) and is_tuple(subtype) do
for t <- Tuple.to_list(subtype), do: validate_type!(t)
end
defp validate_type!(%Reference{} = reference) do
reference
end
defp validate_type!(type) do
raise ArgumentError, """
invalid migration type: #{inspect(type)}. Expected one of:
* an atom, such as :string
* a quoted atom, such as :"integer unsigned"
* an Ecto.Type, such as Ecto.UUID
* a tuple of the above, such as {:array, :integer} or {:array, Ecto.UUID}
* a reference, such as references(:users)
All Ecto types are allowed and properly translated.
All other types are sent to the database as is.
"""
end
defp validate_index_opts!(opts) when is_list(opts) do
case Keyword.get_values(opts, :where) do
[_, _ | _] ->
raise ArgumentError,
"only one `where` keyword is supported when declaring a partial index. " <>
"To specify multiple conditions, write a single WHERE clause using AND between them"
_ ->
:ok
end
end
defp validate_index_opts!(opts), do: opts
defp validate_precision_opts!(opts, column) when is_list(opts) do
if opts[:scale] && !opts[:precision] do
raise ArgumentError, "column #{Atom.to_string(column)} is missing precision option"
end
end
@doc false
def __prefix__(%{prefix: prefix} = index_or_table) do
runner_prefix = Runner.prefix()
cond do
is_nil(prefix) ->
prefix = runner_prefix || Runner.repo_config(:migration_default_prefix, nil)
%{index_or_table | prefix: prefix}
is_nil(runner_prefix) or runner_prefix == to_string(prefix) ->
index_or_table
true ->
raise Ecto.MigrationError, message:
"the :prefix option `#{prefix}` does not match the migrator prefix `#{runner_prefix}`"
end
end
@doc false
def __primary_key__() do
case Runner.repo_config(:migration_primary_key, []) do
false ->
false
opts when is_list(opts) ->
opts = Keyword.put(opts, :primary_key, true)
{name, opts} = Keyword.pop(opts, :name, :id)
{type, opts} = Keyword.pop(opts, :type, :bigserial)
{name, type, opts}
end
end
end
